Factors for extending the ability of isolated pluripotent stem cells to generate extraembryonic lineages in vivo, following in vitro culture, herein, chemical extenders of pluripotency (CEP). Methods of extending the ability of a pluripotent cell to generate embryonic and extraembryonic lineages. The cell to be reprogrammed is contacted with effective amounts of the CEPs for a sufficient period of time to reprogram the cell into a chemically induced extended pluripotent cell (ciEPSC). ciEPSC are identified as an extended pluripotent cell based on properties including: (i) morphologically and (ii) functionally for example, based on their ability contribute to both TE and ICM, in vivo. The ciEPSCs can be cultured or induced to differentiate into cells of a desired type, and used in a number of applications, including but not limited to cell therapy and tissue engineering.

Methods are disclosed for correcting a mutant allele of a gene of interest in a primate cell. The methods include a) introducing a non-naturally occurring targeted nuclease and site-specific nucleotide-binding guide that act together to introduce double-stranded breaks in the mutant allele into the primate cell, wherein: i) the primate cell is undergoing mitotic cell division; ii) the primate cell comprises a genome that is heterozygous for the mutant allele, such that the genome comprises one copy of the mutant allele and one copy of a wild-type allele; iii) single-stranded oligonucleotides homologous to the wild-type allele are not introduced into the primate cell. The methods also include b) allowing the primate cell to activate homology-directed repair of the double-stranded DNA breaks in the mutant allele, thereby correcting the mutant allele using the normal wild-type allele as a repair template and producing a primate cell that is homozygous for the wild-type allele. The primate cell can be a one-cell embryo and/or a human cell.

Methods are disclosed for correcting a mutant allele of a gene of interest in a primate cell. The methods include a) introducing a non-naturally occurring targeted nuclease and site-specific nucleotide-binding guide that act together to introduce double-stranded breaks in the mutant allele into the primate cell, wherein: i) the primate cell is undergoing mitotic cell division; ii) the primate cell comprises a genome that is heterozygous for the mutant allele, such that the genome comprises one copy of the mutant allele and one copy of a wild-type allele; iii) single-stranded oligonucleotides homologous to the wild-type allele are not introduced into the primate cell. The methods also include b) allowing the primate cell to activate homology-directed repair of the double-stranded DNA breaks in the mutant allele, thereby correcting the mutant allele using the normal wild-type allele as a repair template and producing a primate cell that is homozygous for the wild-type allele. The primate cell can be a one-cell embryo and/or a human cell.

The present invention provides modified oocytes having a nuclear genome derived from a first oocyte and cytoplasm derived from a second oocyte from a different subject, and methods for making and using such modified oocytes. The methods and compositions of the present invention can be useful in a variety of settings including, but not limited to, in in vitro fertilization (IVF) procedures.

The present invention provides modified oocytes having a nuclear genome derived from a first oocyte and cytoplasm derived from a second oocyte from a different subject, and methods for making and using such modified oocytes. The methods and compositions of the present invention can be useful in a variety of settings including, but not limited to, in in vitro fertilization (IVF) procedures.

The invention relates to a carrying device for beverage cans which allows the manual carrying of beverage cans grouped together in the form of a pack, which device comprises a body devoid of side walls, having on its surface at least one opening defining a contour with proportions which allow the tight passage therethrough of a beverage can, the contour of said opening having a plurality of tabs that can be folded or bent in relation to the body itself and extending into the same opening, said tabs having a distribution according to at least one sequence, said sequence comprising two contiguous tabs followed by a gap followed by another tab followed by another gap.

Disclosed herein, are inducible immunodeficient animals and methods to make them by adding an IL2Rg/RAG2 rescue cassette (RG-reg) or an IL2Rg/RAG2/FAH rescue cassette (FRG-reg) to a line of IL2Rg/RAG2 knockout (RG-KO) or IL2Rg/RAG2/FAH knockout (FRG-KO) swine. The rescue cassette enables line breeding of immunocompetent (regRG-KO) or (regFRG-KO) swine for rapid propagation. The rescue cassette can be excised, specifically in germ cells of regRG-KO or regFRG-KO swine, such that offspring of animals do not possess the rescue cassette and are immunodeficient. The immunodeficient swine also provide host embryos having genetic ablations to provide a niche for organ complementation by human stem cells.

Disclosed herein, are inducible immunodeficient animals and methods to make them by adding an IL2Rg/RAG2 rescue cassette (RG-reg) or an IL2Rg/RAG2/FAH rescue cassette (FRG-reg) to a line of IL2Rg/RAG2 knockout (RG-KO) or IL2Rg/RAG2/FAH knockout (FRG-KO) swine. The rescue cassette enables line breeding of immunocompetent (regRG-KO) or (regFRG-KO) swine for rapid propagation. The rescue cassette can be excised, specifically in germ cells of regRG-KO or regFRG-KO swine, such that offspring of animals do not possess the rescue cassette and are immunodeficient. The immunodeficient swine also provide host embryos having genetic ablations to provide a niche for organ complementation by human stem cells.

The present invention relates to a method of preparing magnetic oocytes and/or embryos by means of nanoparticles for assisted reproduction techniques and to the use in assisted reproduction techniques of non-human oocytes and/or embryos prepared with said method. Said method comprises: a step in which magnetic nanoparticles are conjugated with oviduct recombinant protein, OVGP1r; a step in which it is verified that the nanoparticle-OVGP1r conjugation attaches to the ZP of oocytes/embryos after being incubated together; and a step in which the number of oocytes/embryos having nanoparticles attached to them distributed around the ZP without being endocytosed is verified; and it is assessed if the amount of magnetic nanoparticles attached to the ZP of oocytes/embryos is enough to be attracted by a magnetic field.

The present invention relates to a method of preparing magnetic oocytes and/or embryos by means of nanoparticles for assisted reproduction techniques and to the use in assisted reproduction techniques of non-human oocytes and/or embryos prepared with said method. Said method comprises: a step in which magnetic nanoparticles are conjugated with oviduct recombinant protein, OVGP1r; a step in which it is verified that the nanoparticle-OVGP1r conjugation attaches to the ZP of oocytes/embryos after being incubated together; and a step in which the number of oocytes/embryos having nanoparticles attached to them distributed around the ZP without being endocytosed is verified; and it is assessed if the amount of magnetic nanoparticles attached to the ZP of oocytes/embryos is enough to be attracted by a magnetic field.